Abstract
Patterning communities is essential to reveal the ecological states of the target ecosystem effectively and consistently. Especially in aquatic ecosystems, the composition of residential communities rapidly varies in response to various impacts of natural and anthropogenic perturbations such as flooding and pollution (Hawkes 1979, Hellawell 1986, Spellerberg 1991). Particular attention has been recently focussed on properly assessing changes in water quality through community patterning. As well documented, field community data are nonlinear and complex because they involve many species, fluctuating greatly depending upon numerous effects of endogenous (e.g., physiological development, life cycle, etc.) and exogenous factors (e.g., precipitation, pollution, etc.) (Jongman et al. 1995, Legendre and Legendre 1998). A complex system like the responses of communities to their environments usually develops a hierarchical structure (Allen and Starr 1982, O'Neill et al. 1986); in particular, benthic macroinvertebrates in streams clearly develop taxonomic and functional hierarchies that are essential to establish organization in communities (Cummins et al. 1973, Cummins 1974). Additionally, habitats of benthic macroinvertebrates in streams are also classified hierarchically, taking into account the fact that variables are revealed differently across different space and time scales on which a system is viewed (Frissell et al. 1986, Minshall 1988). Since a hierarchical nature is an essential part of stream ecosystems, the determination of the appropriate methods of examination has been a key concept in investigating aquatic ecosystems (Minshall 1993). Consequently, the hierarchical classification approaches could provide in-depth and comprehensive understanding of community organization and water quality in the target ecosystem. Assessment of water quality and prediction of community dynamics in streams are essential for diagnosing ecosystem health and for providing policies of sustainable management of stream ecosystems. Especially benthic macroinvertebrate communities are effective in indicating water quality and could effectively reveal ecological states of the target aquatic ecosystem. They constitute a heterogeneous assemblage of animal phyla, and consequently it is probable that some members will always respond to stresses placed upon them (Hynes 1960, Hawkes 1979, Hellawell 1986). Communities have been analyzed by conventional multivariate statistical methods (Ludwig and Reynolds 1988, Jongman et al. 1995, Legendre and Legendre 1998), however they are limited in extracting information effectively out of complex data. As an alternative tool to deal with this problem of complexity in ecological data, artificial neural networks (ANNs) have been utilized for patterning
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